Embodiments of golf club face plates with internal cell lattices are presented herein. Other examples and related methods are also disclosed herein.
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23. A method for providing a face plate for a golf club head, the method comprising:
providing an inner skin of the face plate;
providing an outer skin of the face plate;
providing a midsection of the face plate; and
coupling the midsection between the inner skin and the outer skin such that:
an inner midsection end of the midsection is coupled to the inner skin of the face plate; and
an outer midsection end of the midsection is coupled to the outer skin of the face plate;
wherein:
providing the midsection comprises:
providing a cell lattice in the midsection, the cell lattice comprising a plurality of walls defining a plurality of cells;
and
providing the cell lattice comprises:
forming a first wall of the plurality of walls to comprise a transverse passageway between adjacent cells of the plurality of cells.
22. A method for providing a face plate for a golf club head, the method comprising:
providing an inner skin of the face plate;
providing an outer skin of the face plate;
providing a midsection of the face plate; and
coupling the midsection between the inner skin and the outer skin such that:
an inner midsection end of the midsection is coupled to the inner skin of the face plate; and
an outer midsection end of the midsection is coupled to the outer skin of the face plate;
wherein:
providing the midsection comprises:
providing a cell lattice in the midsection, the cell lattice comprising a plurality of walls defining a plurality of cells;
and
providing the cell lattice comprises:
providing a plurality of cell junctions where two or more of the plurality of walls couple together; and
forming a first junction channel into a first cell junction of the plurality of cell junctions, the first junction channel extending from the inner midsection end to the outer midsection end.
21. A method for providing a face plate for a golf club head, the method comprising:
providing an inner skin of the face plate;
providing an outer skin of the face plate;
providing a midsection of the face plate; and
coupling the midsection between the inner skin and the outer skin such that:
an inner midsection end of the midsection is coupled to the inner skin of the face plate; and
an outer midsection end of the midsection is coupled to the outer skin of the face plate;
wherein:
providing the midsection comprises:
providing a cell lattice in the midsection, the cell lattice comprising a plurality of walls defining a plurality of cells;
coupling the midsection comprises:
merging the inner skin, the midsection, and the outer skin together into a single integral piece of material without adhesives or fasteners;
merging the inner skin, the midsection, and the outer skin together via diffusion bonding using a high-pressure and high-heat process; and
a metallic material of the midsection comprises a titanium alloy comprising at least approximately 8% aluminum.
2. A method for providing a face plate for a golf club head, the method comprising:
providing an inner skin of the face plate;
providing an outer skin of the face plate;
providing a midsection of the face plate; and
coupling the midsection between the inner skin and the outer skin such that:
an inner midsection end of the midsection is coupled to the inner skin of the face plate; and
an outer midsection end of the midsection is coupled to the outer skin of the face plate;
wherein:
providing the midsection comprises:
providing a cell lattice in the midsection, the cell lattice comprising a plurality of walls defining a plurality of cells;
prior to coupling the midsection between the inner skin and the outer skin:
the inner skin comprises a first crystal structure of an alpha-type structure;
the outer skin comprises a second crystal structure of the alpha-type structure; and
the midsection comprises a midsection crystal structure of the alpha-type structure;
and
coupling the midsection between the inner skin and the outer skin comprises:
transforming the first crystal structure, the second crystal structure, and the midsection crystal structure to a beta-type structure such that:
the midsection crystal structure is intermeshed with the first crystal structure; and
the midsection crystal structure is intermeshed with the second crystal structure.
24. A face plate for a golf club head, the face plate comprising:
a face plate central area
a face plate perimeter area between the face plate central area and a perimeter of the face plate;
an inner skin;
an outer skin; and
a midsection comprising:
an inner midsection end coupled to the inner skin;
an outer midsection end coupled to the outer skin; and
a cell lattice comprising a plurality of walls defining a plurality of cells between the inner midsection end and the outer midsection end;
wherein:
the inner skin comprises a first crystal structure;
the outer skin comprises a second crystal structure;
the midsection comprises a plurality of midsection layers having a midsection crystal structure;
the inner skin, the outer skin, and the midsection, along with the plurality of midsection layers, comprise a single piece of material;
the midsection comprises a metallic material;
the inner skin and the outer skin comprise the metallic material;
the cell lattice is located in the face plate central area without extending into the face plate perimeter area and
the cell lattice comprises a hexagonal pattern defined by the plurality of walls;
the metallic material comprises a titanium alloy comprising at least approximately 8% aluminum;
the first, second, and midsection crystal structures comprise a beta-type structure having a body-centered cubic crystal phase; and
the cell lattice comprises an isogrid pattern defined by the plurality of walls and the plurality of cells.
1. A method for providing a face plate for a golf club head, the method comprising:
providing an inner skin of the face plate;
providing an outer skin of the face plate;
providing a midsection of the face plate; and
bounding the midsection between the inner skin and the outer skin;
wherein:
providing the midsection comprises:
providing a plurality of midsection layers comprising a first midsection layer and a second midsection layer;
forming a first lattice pattern through the first midsection layer; and
forming a second lattice pattern through the second midsection layer;
providing the inner skin, the outer skin, and the midsection comprises:
providing each of the midsection, the inner skin, or the outer skin as separate distinct pieces;
bounding the midsection comprises:
diffusion bonding the inner skin, the midsection, and the outer skin together, including the first and second midsection layers, into a single integral piece of material that is substantially seamless between the inner skin and the midsection and between the midsection and the outer skin;
wherein after the diffusion bonding:
a midsection central area of the midsection comprises a cell lattice;
the cell lattice comprises a plurality of walls defining a plurality of cells in a hexagonal pattern;
the plurality of walls and the plurality of cells of the cell lattice are defined at least in part by the first and second lattice patterns;
the cell lattice is fully bounded between the inner and outer skins of the face plate; and
a midsection perimeter area of the midsection bounds the midsection central area and is devoid of the cell lattice;
forming the first lattice pattern through the first midsection layer comprises forming a first cutout through the first midsection layer, the first cutout configured to define a first volume portion of a first cell of the cell lattice;
forming the second lattice pattern through the second midsection layer comprises forming a second cutout through the second midsection layer, the second cutout configured to define a second volume portion of the first cell;
bounding the midsection comprises:
aligning the second midsection layer over the first midsection layer such that the first and second cutouts are centered about a first cell axis of the first cell;
bounding the midsection comprises
forming the plurality of cells in an isogrid pattern;
diffusion bonding the inner skin, the midsection, and the outer skin together comprises intermeshing interfaces between the inner skin, the midsection, and the outer skin together via a high-pressure and high-heat process;
providing the inner skin, the outer skin, and the midsection comprises;
providing the midsection, the inner skin, and the outer skin to each comprise a titanium alloy with an alpha-type crystal structure;
and
diffusion bonding the inner skin, the midsection, and the outer skin together comprises
transforming the alpha-type crystal structure of the midsection, the inner skin, and the outer skin to a beta-type crystal structure intermeshing the midsection, the inner skin, and the outer skin together;
the alpha-type crystal structure comprising a hexagonal crystal phase; and
the beta-type crystal structure comprises a body-centered cubic crystal phase.
3. The method of
coupling the midsection comprises:
merging the inner skin, the midsection, and the outer skin together into a single integral piece of material without adhesives or fasteners.
4. The method of
the single integral piece of material is seamless between the inner skin and the midsection and between the midsection and the outer skin.
5. The method of
coupling the midsection comprises:
merging the inner skin, the midsection, and the outer skin together via diffusion bonding using a high-pressure and high-heat process.
6. The method of
the midsection comprises a metallic material; and
the inner skin and the outer skin comprise the metallic material.
7. The method of
providing the cell lattice comprises:
providing the cell lattice extended from the inner midsection end to the outer midsection end.
8. The method of
providing the midsection comprises:
forming the cell lattice in a midsection central area of the midsection; and
providing a midsection perimeter area of the midsection bounding the midsection central area and devoid of the cell lattice.
9. The method of
coupling the face plate to a front end of the golf club head;
wherein coupling the face plate to the front end of the golf club head comprises:
coupling the front end of the golf club head to at least one of:
an inner skin perimeter area of the inner skin; or an outer skin perimeter area of the outer skin;
the inner skin perimeter area and the outer skin perimeter area being coupled to the midsection perimeter area without contacting the cell lattice at the midsection central area.
10. The method of
providing the cell lattice comprises forming one or more of the plurality of cells with at least one of a hexagonal shape, a diamond shape, a rectangular shape, a circular shape, or a triangular shape.
11. The method of
providing the cell lattice comprises:
providing cells of a first set of the plurality of cells with a first geometric shape; and
providing cells of a second set of the plurality of cells with a second geometric shape different than the first geometric shape; and
providing the first set of the plurality of cells interspersed with the second set of the plurality of cells.
12. The method of
providing the cell lattice comprises forming one or more subcells within one or more of the plurality of cells.
13. The method of
forming the cell lattice comprises forming the plurality of cells in an isogrid pattern.
14. The method of
providing the cell lattice comprises:
forming a first wall of the plurality of walls to comprise a varying wall dimension.
15. The method of
providing the cell lattice comprises forming the plurality of cells in at least one of:
a first pattern where a density of the plurality of cells decreases towards a target strike region of the face plate; or
a second pattern where a size of the plurality of cells decreases towards the target strike region of the face plate.
16. The method of
providing the midsection comprises:
providing a plurality of midsection layers comprising:
a first midsection layer; and
a second midsection layer;
providing the cell lattice in the midsection comprises:
forming a first lattice pattern of the cell lattice through the first midsection layer; and
forming a second lattice pattern of the cell lattice through the second midsection layer;
and
coupling the midsection between the inner skin and the outer skin comprises:
merging the first midsection layer and the second midsection layer together integrally into a single piece of material.
17. The method of
providing the cell lattice comprises forming a first cell of the plurality of cells;
forming the first lattice pattern through the first midsection layer comprises:
forming a first cutout through the first midsection layer, the first cutout configured to define a first volume portion of the first cell;
and
forming the second lattice pattern through the second midsection layer comprises:
forming a second cutout through the second midsection layer, the second cutout configured to define a second volume portion of the first cell.
18. The method of
forming the second cutout comprises:
forming the second cutout to comprise a different dimension than the first cutout, the different dimension comprising at least one of:
a different radius, a different perimeter length, a different area, or a different volume.
19. The method of
prior to merging the first midsection layer and the second midsection layer together:
forming the cell lattice comprises:
aligning the second midsection layer over the first midsection layer such that the first and second cutouts are centered about a first cell axis of the first cell.
20. The method of
providing the cell lattice comprises forming a first cell of the plurality of cells;
forming the first lattice pattern through the first midsection layer comprises:
forming a first cutout through the first midsection layer, the first cutout configured to define a first volume portion of the first cell;
prior to merging the first midsection layer and the second midsection layer together:
forming the second lattice pattern of the cell lattice through the second midsection layer comprises:
forming a second cutout through the second midsection layer, the second cutout configured to define a second volume portion of a second cell of the cell lattice;
and
providing the cell lattice further comprises:
aligning the first midsection layer over the second midsection layer such that:
the first and second cells are offset relative to each other;
the second cell is at least partially capped by a solid portion of the first midsection layer; and
the first cell is at least partially capped by a solid portion of the second midsection layer.
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This is a non-provisional utility patent application claiming priority to U.S. Provisional Patent Application No. 61/537,278, filed on Sep. 21, 2011, and titled “Golf Club Face Plates With Internal Cell Lattices And Related Methods.” The contents of the disclosure listed above are incorporated herein by reference.
The present disclosure relates generally to sports equipment, and relates, more particularly, to golf club face plates with internal cell lattices and related methods.
The development of golf club head technology has been characterized in part by the desire to enhance playability characteristics while managing weight and mass location considerations. The ability to alter or redistribute mass at or around locations of high stress and/or of limited thickness in a golf club head, however, has to be balanced with respect to structural resilience considerations. Considering the above, further developments in terms of weight redistribution will advance the playability characteristics of golf club heads.
The present disclosure will be better understood from a reading of the following detailed description of examples of embodiments, taken in conjunction with the accompanying figures in the drawings.
For simplicity and clarity of illustration, the drawing figures illustrate the general manner of construction, and descriptions and details of well-known features and techniques may be omitted to avoid unnecessarily obscuring the present disclosure. Additionally, elements in the drawing figures are not necessarily drawn to scale. For example, the dimensions of some of the elements in the figures may be exaggerated relative to other elements to help improve understanding of embodiments of the present disclosure. The same reference numerals in different figures denote the same elements.
The terms “first,” “second,” “third,” “fourth,” and the like in the description and in the claims, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the terms so used are interchangeable under appropriate circumstances such that the embodiments described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms “include,” and “have,” and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, device, or apparatus that comprises a list of elements is not necessarily limited to those elements, but may include other elements not expressly listed or inherent to such process, method, system, article, device, or apparatus.
The terms “left,” “right,” “front,” “back,” “top,” “bottom,” “over,” “under,” and the like in the description and in the claims, if any, are used for descriptive purposes and not necessarily for describing permanent relative positions. It is to be understood that the terms so used are interchangeable under appropriate circumstances such that the embodiments of the apparatus, methods, and/or articles of manufacture described herein are, for example, capable of operation in other orientations than those illustrated or otherwise described herein.
The terms “couple,” “coupled,” “couples,” “coupling,” and the like should be broadly understood and refer to connecting two or more elements or signals, electrically, mechanically or otherwise. Two or more electrical elements may be electrically coupled, but not mechanically or otherwise coupled; two or more mechanical elements may be mechanically coupled, but not electrically or otherwise coupled; two or more electrical elements may be mechanically coupled, but not electrically or otherwise coupled. Coupling (whether mechanical, electrical, or otherwise) may be for any length of time, e.g., permanent or semi-permanent or only for an instant.
“Mechanical coupling” and the like should be broadly understood and include mechanical coupling of all types. The absence of the word “removably,” “removable,” and the like near the word “coupled,” and the like does not mean that the coupling, etc. in question is or is not removable.
As defined herein, two or more elements are “integral” if they are comprised of the same piece of material. As defined herein, two or more elements are “non-integral” if each is comprised of a different piece of material.
In one embodiment, a method for providing a face plate for a golf club head can comprise providing an inner skin of the face plate, providing an outer skin of the face plate, providing a midsection of the face plate, and bounding the midsection between the inner skin and the outer skin. Providing the midsection can comprise providing a plurality of midsection layers comprising a first midsection layer and a second midsection layer, forming a first lattice pattern through the first midsection layer, and forming a second lattice pattern through the second midsection layer. Providing the inner skin, the outer skin, and the midsection can comprise providing each of the midsection, the inner skin, or the outer skin as separate distinct pieces. Bounding the midsection can comprise diffusion bonding the inner skin, the midsection, and the outer skin together, including the first and second midsection layers, into a single integral piece of material that is substantially seamless between the inner skin and the midsection and between the midsection and the outer skin. After the diffusion bonding, a midsection central area of the midsection can comprise a cell lattice, the cell lattice can comprise a plurality of walls defining a plurality of cells in a hexagonal pattern, the plurality of walls and the plurality of cells of the cell lattice can be defined at least in part by the first and second lattice patterns, the cell lattice can be fully bounded between the inner and outer skins of the face plate, and a midsection perimeter area of the midsection can bound the midsection central area and can be devoid of the cell lattice. Forming the first lattice pattern through the first midsection layer can comprise forming a first cutout through the first midsection layer, the first cutout configured to define a first volume portion of a first cell of the cell lattice. Forming the second lattice pattern through the second midsection layer can comprise forming a second cutout through the second midsection layer, the second cutout configured to define a second volume portion of the first cell. Bounding the midsection can comprise aligning the second midsection layer over the first midsection layer such that the first and second cutouts are centered about a first cell axis of the first cell.
In one embodiment, a method for providing a face plate for a golf club head can comprise providing an inner skin of the face plate, providing an outer skin of the face plate, providing a midsection of the face plate, and coupling the midsection between the inner skin and the outer skin such that an inner midsection end of the midsection is coupled to the inner skin of the face plate, and such that an outer midsection end of the midsection is coupled to the outer skin of the face plate. Providing the midsection can comprise providing a cell lattice in the midsection, the cell lattice comprising a plurality of walls defining a plurality of cells.
In one embodiment, a face plate for a golf club head can comprise an inner skin, an outer skin, and a midsection. The midsection can comprise an inner midsection end coupled to the inner skin, an outer midsection end coupled to the outer skin, and a cell lattice comprising a plurality of walls defining a plurality of cells between the inner midsection end and the outer midsection end.
Other examples and embodiments are further disclosed herein. Such examples and embodiments may be found in the figures, in the claims, and/or in the present description.
Turning to the drawings,
The different portions of faceplate 100 can comprise different thicknesses. In the present example, the thickness of outer skin 120 is approximately 0.03 inches (approximately 0.08 millimeters (mm); the thickness of midsection 230 is approximately 0.07 inches (approximately 1.78 mm); and the thickness of inner skin varies, being approximately 0.05 inches (approximately 0.13 mm) towards the center, and approximately 0.03 inches (approximately 0.08 mm) towards the perimeter. The thickness of inner skin 210 is greater than the thickness of outer skin 120 in the present example, where inner skin 210 faces away from the impact surface of faceplate 100, to better distribute impact stresses throughout the faceplate. In some examples, the thickness of inner skin 210 and outer skin 120 can be substantially similar to each other, and/or may not vary.
In the present example, face plate 100 is shown with inner skin 210, outer skin 120, and midsection 230 merged together into a single integral piece of material. In some examples, inner skin 210, outer skin 120, and/or midsection 230 may be merged together without using adhesives or fasteners, such as via a high-pressure and/or high-heat process. In the same or other examples, such process may comprise a diffusion bonding process. The ability to combine midsection 230 between inner skin 210 and outer skin 120 and into a single integral piece of material can provide many benefits, such as a reduction in the weight of face plate 100 via cell lattice 240. In some examples, encapsulating cell lattice 240 within face plate 100 can permit weight savings of approximately 8% to approximately 25%. Such results can be achieved without compromising the strength or durability of face plate 100, and without introducing detrimental bending, elastic and/or flexing susceptibilities that would result from uneven stress distribution if, for example, face plate 100 were made with cell lattice 240 exposed and/or without one of inner skin 210 or outer skin 120. As an example, and skipping ahead in the figures,
Backtracking to
Although in the present example the cutouts of lattice pattern 341 are all similar to each other, there can be other examples where the cutouts can have different geometries, different dimensions, such as different radiuses, different perimeter lengths, different areas, and/or different volumes. The same or other examples may comprise other patterns, such as a pattern where a density in the number of cells 242 decreases towards target strike region 150 of face plate 100, and/or a pattern where a size or dimension of cells 242 decreases towards target strike region 150 of face plate 100.
Referring to
In the present example, each of layers 300 of face plate 100 comprises the same type of material. As an example, midsection 230, inner skin 210, and outer skin 120, and respective midsection layers 330, inner skin layers 310, and outer skin layers 320, comprise a metallic material such as a metallic alloy. In the present example, individual ones of layers 300, such as layer 331, can comprise a thickness of approximately 0.01 inch or approximately 0.25 mm. In the same or other embodiments, one or more of such layers 300 can comprise a thickness ranging from between approximately 0.25 mm to approximately 2.54 mm.
In the present embodiment, the metallic material for layers 300 of face plate 100 can comprise a titanium alloy comprising at least approximately 8% aluminum (by volume). In the same or other examples, the metallic alloy can comprise a titanium 8-1-1 alloy having approximately 8% aluminum, 1% vanadium and 1% chromium. Other materials may be used depending on their strength, considering their brittleness/elasticity as a beta-type crystal structure. For example, a titanium 6-4 alloy having approximately 6% aluminum and 4% vanadium, may be used in some embodiments, but can be from 5% to 12% less elastic than titanium 8-1-1 and may thus require further reinforcement or thickness for face plate 100 to properly withstand golf impact stresses. In contrast, other materials such as commercially pure titanium, may not be suitable to properly withstand the stresses to which face plate 100 is subjected.
There can be examples where the metallic alloy of layers 300 may comprise an alpha-type crystal structure prior to being merged together, and a stronger beta-type crystal structure after being merged together, such as via the high-heat and high pressure process described above. As an example, the alpha-type crystal structure may comprise a hexagonal crystal phase, and/or the beta-type crystal structure may comprise a body-centered cubic crystal phase. The transformation to beta-type crystal structure can permit the crystal structure of adjacent layers of layers 300 to be intermeshed together at a molecular level once the merging process is completed to yield the single integral piece of material for face plate 100.
As can be seen in
In the present example, face plate 100 comprises cell lattice 240 in a central area of midsection 230, as can be seen from the exemplary midsection layer 331 shown in
Cell lattice 240 comprises a hexagonal isogrid pattern with six subcells per hexagon in the present example, as can be seen in
Continuing with the figures,
Also in the present example, one or more of the cell junctions can comprise respective junction channels, such as junction channel 4431 extending into cell junction 443 from inner midsection end 245 to outer midsection end 246. Junction channel 4431 comprises a largest dimension or diameter of approximately 0.015 inches (approximately 0.38 mm) in the present example, but there can be examples where similar junction channels can comprise a diameter and/or largest dimension of approximately 0.2 mm to approximately 0.66 mm.
In addition, cell lattice 240 also comprises one or more transverse passageways in the present example, such as transverse passageway 644 between at least two adjacent cells of cells 242. Transverse passageway 644 comprises a largest dimension or diameter of approximately 0.05 inches (approximately 1.27 mm) in the present example, but there can be examples where similar transverse passageways can comprise a diameter and/or largest dimension of approximately 0.5 mm to approximately 1.27 mm.
The addition of features such as junction channel 4431 and transverse passageway 644 can permit additional reduction in weight without compromising the strength or integrity of face plate 100. Also, the geometry and/or shape of junction channel 4431 and/or passageway 644 can be changed to be the same geometry and/or shape as cells 242 or another geometry and/or shape. Additionally, different ones of junction channel 4431 and/or passageway 644 can have different geometries and/or shapes.
Skipping ahead in the figures,
Backtracking through the figures,
There can be other examples, however, that can comprise cell lattices with other types of geometrical shapes, dimensions, or combinations thereof. For instance skipping ahead to
There also can be examples where individual cells of a cell lattice can comprise subcells therewithin. For example, cells 242 (
Although cell lattices 1240 (
In some examples, the height of the cells of a cell lattice may vary from cell to cell. As an example,
In the same or other examples, the size of cells 18242 can decrease or increase as a function of distance from the center of target strike region 18150. In other examples, however, the size and/or concentration of cells 18242 can change relative to another feature of the faceplate, such as by increasing or decreasing from top edge to bottom edge or the face plate, and/or such as by increasing or decreasing from heel end to toe end of the face plate. In some embodiments, cells 18242 can decrease in size or dimension between approximately 1% to approximately 10% from cell to cell as the distance to the center of target strike region 18150 shortens. In the same or other embodiments, a distance between cells 18242 can increase between approximately 1% to approximately 10% from cell to cell as the distance to the center of target strike region 18150 shortens. There can also be example where the change in size or concentration of cells 18242, relative to the center of target strike region 18150, can change in a non-linear and/or a step function fashion.
Although cells 18242 of cell lattice 18240 are illustrated in
In some examples, center lattice region 19510 may be similar to or correspond to target strike region 150 of face plate 100 (
In the present example, center lattice region 20510 can be stiffer than heel lattice region 20521 and toe lattice region 20522, while the stiffnesses of heel lattice region 20521 and of toe lattice region 20522 can be similar to each other. There can also be examples, however, where the stiffnesses of heel lattice region 20521 can be greater than the stiffness of toe lattice region 20522, or vice-versa. The ability to establish such different stiffness options for the different regions of faceplate 20100 can permit, for example, an optimization of ball speed due to differences in club head speed across the faceplate as induced by club head rotation about the golf shaft axis during swinging, the offsetting of a bias in average impact location, and/or the fine-tuning of the shape or position of the club head's target strike region. In addition, cell lattice regions 20500 are separated from each other by one or more boundary channels 20600 in the present example. Boundary channels 20600 are devoid of a cell lattice therewithin, but there also can be examples where boundary channels 20600 can comprise a cell lattice similar to one or more of the cell lattices described herein. In other examples, however, faceplate 20100 can be devoid of boundary channels 20600, such that cell lattice regions 20500 contact or merge into each other.
In the present example, center lattice region 21510 can be stiffer than periphery lattice regions 21520. The stiffnesses of periphery lattice regions 21520 can be similar to each other or differ from each other, depending on the embodiment. For example, the stiffness of top lattice region 21523 and of bottom lattice region 21524 may be stiffer than the stiffnesses of heel lattice region 21521 and of toe lattice region 21522, or vice-versa. There can also be examples where each of periphery lattice regions 21520 can comprise a different stiffness. The ability to establish such different stiffness options for the different regions of faceplate 21100 can permit further alternatives regarding benefits similar to those described above with respect to faceplate 20100. In the present example, cell lattice regions 21500 are separated from each other by one or more boundary channels 21600, which can be similar to boundary channels 20600 (
Backtracking through the figures,
Block 10100 of method 10000 comprises providing an inner skin of the face plate. Block 10200 of method 10000 comprises providing an outer skin of the face plate. In some examples, the inner skin of block 10100 can be similar to inner skin 210, while the outer skin of block 10200 can be similar to outer skin 120 (
Block 10300 of method 10000 comprises providing a midsection of the face plate. In some examples, the midsection can be similar to midsection 230 (
In some examples, block 10300 can also comprise sub-block 10320 for forming a cell lattice in the midsection, the cell lattice comprising a plurality of walls defining a plurality of cells. In some examples, the cell lattice can be similar to cell lattice 240 of midsection 230 (
Sub-block 10320 may comprise sub-block 10321 for forming a first lattice pattern of the cell lattice through the first midsection layer, and/or sub-block 10322 for forming a second lattice pattern of the cell lattice through the second midsection layer. In some examples, the first lattice pattern of sub-block 10321 can be similar to cell lattice pattern 341 through midsection layer 331 (
Sub-block 10321 may comprise forming a first cutout through the first midsection layer, where the first cutout is configured to define a first volume portion of a first cell of the cell lattice. Similarly, sub-block 10322 may comprise forming a second cutout through the second midsection layer, where the second cutout is configured to define a second volume portion of the first cell of the cell lattice. As an example, the first cutout may be similar to cutout 342 through midsection layer 331 (
In some examples, forming the cell lattice in block 10320 can comprise aligning the second midsection layer over the first midsection layer such that the first and second cutouts are centered about a first cell axis of a cell of cell lattice 240. As an example, as described above with respect to
There can also be examples where not all cutouts of stacked layers of the midsection need be aligned with each other centered about a cell axis. In some embodiments, the cutouts and/or cells of the cell lattice may be offset from each other. For instance, forming the first lattice pattern in block 10321 can comprise forming the first cutout through the first midsection layer to define a first volume portion of the first cell, and forming the second lattice pattern block 10322 can comprise forming the second cutout through the second midsection layer to define a second volume portion of a second cell of the cell lattice. In the same or other examples, the second cell can be at least partially capped or defined by solid portions of the first midsection layer and/or the outer skin, and/or the first cell can be at least partially capped or defined by solid portions of the second midsection layer and/or the inner skin. For instance, as shown in
Block 10400 of method 10000 comprises coupling the midsection of block 10300 between the inner skin of block 10100 and the outer skin of block 10200. In some examples, the midsection may comprise an inner midsection end coupled to the inner skin of block 10100, and an outer midsection end coupled to the outer skin of block 10200, such that the midsection is “sandwiched” therebetween. In the same or other examples, block 10400 can comprise sub-block 10410 for merging the inner skin, the midsection, and the outer skin together into a single integral piece of material without adhesives or fasteners. For instance, the inner skin, the midsection, and the outer skin may be merged together via a high-heat and high-pressure process as described above with respect to
Such seamless and single-piece merging between the inner skin, the mid section and the outer skin, and/or between their respective layers, can occur when the merging occurs at the molecular level. For example, the inner skin, the midsection, and the outer skin can all be provided to comprise the same metallic material, where such material can be selected to be suitable for merging the different portions of the faceplate at the molecular level when exposed to a high heat and high-pressure process, such as through a diffusion bonding process. In some examples, the metallic material can comprise a metallic alloy, as described above, and the merging at the molecular level can take advantage of the crystal structure of the metallic material to achieve integral bonding to generate the single piece of material for the faceplate. As an example, the inner skin may be provided in block 10100 to comprise a first crystal structure of an alpha-type structure; the outer skin may be provided in block 10200 to comprise a second crystal structure of the alpha-type structure; and the midsection may be provided in block 10300 to comprise a midsection crystal structure of the alpha-type structure. Then, at block 10400, the first crystal structure of the inner skin, the second crystal structure of the outer skin, and the midsection crystal structure of the midsection can be transformed into a beta-type structure such that the midsection crystal structure is intermeshed with the first crystal structure, and the midsection crystal structure is intermeshed with the second crystal structure. In some examples, the alpha-type structure can comprise a hexagonal crystal phase, and the beta-type structure can comprises a body-centered cubic crystal phase.
Block 10500 of method 10000 can be optional, comprising coupling the face plate to a front end of the golf club head. In some examples, the golf club head can be similar to golf club head 10 as illustrated in
In some examples, the cell lattice of the midsection, as formed in sub-block 10320, can be located in a central midsection area of the midsection, such that a perimeter midsection area of the midsection bounding the central midsection area can be devoid of the cell lattice and/or of its cells. As an example, the perimeter midsection area can be similar to perimeter midsection area 232 of midsection 230 bounding the central area of midsection 230 comprising cell lattice 240 (
In the same or other examples, coupling the face plate in block 10500 can comprise coupling the front end of the golf club head to an inner skin perimeter area of the inner skin of block 10100, such as to inner skin perimeter area 212 (
The cell lattice formed in block 10320 can comprise one or more of several characteristics. For example, the plurality of cells of the cell lattice can be formed in a hexagonal pattern, such as seen in FIGS. 4 and 6-7 with respect to cell lattice 240. In the same or other examples, the cell lattice can be formed in an isogrid pattern, as also seen with respect to cell lattices 240 and 740. The cell lattice can comprise in the same or other examples a plurality of cell junctions where two or more of the plurality of walls couple together. For instance, the cell junctions can be similar to cell junction 443 (
Continuing with examples of the one or more several characteristics for the cell lattice in block 10320, there can also be embodiments where forming the cell lattice can comprise forming one or more walls of the cell lattice to comprise a varying dimension. As an example, the cell lattice can comprise a wall, such as one of walls 741 having varying length thickness dimensions (
In the same or other examples, the cell lattice can comprise one or more transverse passageways between adjacent cells of the cell lattice. As an example, the cell lattice can comprise transverse passageways as shown in
There can also be examples where a single faceplate can comprise a plurality of cell lattice regions, such as described with respect to
In some examples, one or more of the different blocks of method 10000 can be combined into a single block or performed simultaneously, and/or the sequence of such blocks can be changed. For example, the inner skin of block 10100 may be provided simultaneously with the midsection of block 10300, and/or the outer skin of block 10200 may be provided simultaneously with the midsection of block 10300. As another example, the sequence of sub-blocks 10321 and 10322 can be changed.
In the same or other examples, some of the blocks of method 10000 can be subdivided into several sub-blocks. For example, block 10500 may comprise a sub-block for fastening the face plate to the front end of the golf club head, and another sub-block for polishing the faceplate and/or the junction with the front end of the golf club head. There can also be examples where method 10000 can comprise further or different blocks. In addition, there may be examples where method 10000 can comprise only part of the steps described above. For instance, block 10500 can be optional in some examples. Other variations can be implemented for method 10000 without departing from the scope of the present disclosure.
Although the golf club face plates with internal cell lattices and related methods herein have been described with reference to specific embodiments, various changes may be made without departing from the spirit or scope of the present disclosure. For example, although golf club head 10 is illustrated in
The golf club face plates with internal cell lattices and related methods discussed herein may be implemented in a variety of embodiments, and the foregoing discussion of certain of these embodiments does not necessarily represent a complete description of all possible embodiments. Rather, the detailed description of the drawings, and the drawings themselves, disclose at least one preferred embodiment, and may disclose alternative embodiments.
All elements claimed in any particular claim are essential to the embodiment claimed in that particular claim. Consequently, replacement of one or more claimed elements constitutes reconstruction and not repair. Additionally, benefits, other advantages, and solutions to problems have been described with regard to specific embodiments. The benefits, advantages, solutions to problems, and any element or elements that may cause any benefit, advantage, or solution to occur or become more pronounced, however, are not to be construed as critical, required, or essential features or elements of any or all of the claims, unless such benefits, advantages, solutions, or elements are expressly stated in such claims.
As the rules to golf may change from time to time (e.g., new regulations may be adopted or old rules may be eliminated or modified by golf standard organizations and/or governing bodies such as the United States Golf Association (USGA), the Royal and Ancient Golf Club of St. Andrews (R&A), etc.), golf equipment related to the apparatus, methods, and articles of manufacture described herein may be conforming or non-conforming to the rules of golf at any particular time. Accordingly, golf equipment related to the apparatus, methods, and articles of manufacture described herein may be advertised, offered for sale, and/or sold as conforming or non-conforming golf equipment. The apparatus, methods, and articles of manufacture described herein are not limited in this regard.
While the above examples may be described in connection with a driver-type golf club, the apparatus, methods, and articles of manufacture described herein may be applicable to other types of golf club such as a fairway wood-type golf club, a hybrid-type golf club, an iron-type golf club, a wedge-type golf club, or a putter-type golf club. Alternatively, the apparatus, methods, and articles of manufacture described herein may be applicable other type of sports equipment such as a hockey stick, a tennis racket, a fishing pole, a ski pole, etc.
Moreover, embodiments and limitations disclosed herein are not dedicated to the public under the doctrine of dedication if the embodiments and/or limitations: (1) are not expressly claimed in the claims; and (2) are or are potentially equivalents of express elements and/or limitations in the claims under the doctrine of equivalents.
Morales, Eric J., Henrikson, Erik
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